Skip to content

Latest commit

 

History

History
183 lines (140 loc) · 7.37 KB

README.md

File metadata and controls

183 lines (140 loc) · 7.37 KB

PointGroup

PointGroup: Dual-Set Point Grouping for 3D Instance Segmentation (CVPR2020)

overview

Code for the paper PointGroup:Dual-Set Point Grouping for 3D Instance Segmentation, CVPR 2020 (Oral).

Authors: Li Jiang, Hengshuang Zhao, Shaoshuai Shi, Shu Liu, Chi-Wing Fu, Jiaya Jia

[arxiv] [video]

Introduction

Instance segmentation is an important task for scene understanding. Compared to the fully-developed 2D, 3D instance segmentation for point clouds have much room to improve. In this paper, we present PointGroup, a new end-to-end bottom-up architecture, specifically focused on better grouping the points by exploring the void space between objects. We design a two-branch network to extract point features and predict semantic labels and offsets, for shifting each point towards its respective instance centroid. A clustering component is followed to utilize both the original and offset-shifted point coordinate sets, taking advantage of their complementary strength. Further, we formulate the ScoreNet to evaluate the candidate instances, followed by the Non-Maximum Suppression (NMS) to remove duplicates.

Installation

Requirements

  • Python 3.7.0
  • Pytorch 1.1.0
  • CUDA 9.0

Virtual Environment

conda create -n pointgroup python==3.7
source activate pointgroup

Install PointGroup

(1) Clone the PointGroup repository.

git clone https://github.com/llijiang/PointGroup.git --recursive 
cd PointGroup

(2) Install the dependent libraries.

pip install -r requirements.txt
conda install -c bioconda google-sparsehash 

(3) For the SparseConv, we apply the implementation of spconv. The repository is recursively downloaded at step (1). We use the version 1.0 of spconv.

Note: We further modify spconv\spconv\functional.py to make grad_output contiguous. Make sure you use our modified spconv.

  • To compile spconv, firstly install the dependent libraries.
conda install libboost
conda install -c daleydeng gcc-5 # need gcc-5.4 for sparseconv

Add the $INCLUDE_PATH$ that contains boost in lib/spconv/CMakeLists.txt. (Not necessary if it could be found.)

include_directories($INCLUDE_PATH$)
  • Compile the spconv library.
cd lib/spconv
python setup.py bdist_wheel
  • Run cd dist and use pip to install the generated .whl file.

(4) Compile the pointgroup_ops library.

cd lib/pointgroup_ops
python setup.py develop

If any header files could not be found, run the following commands.

python setup.py build_ext --include-dirs=$INCLUDE_PATH$
python setup.py develop

$INCLUDE_PATH$ is the path to the folder containing the header files that could not be found.

Data Preparation

(1) Download the ScanNet v2 dataset.

(2) Put the data in the corresponding folders.

  • Copy the files [scene_id]_vh_clean_2.ply, [scene_id]_vh_clean_2.labels.ply, [scene_id]_vh_clean_2.0.010000.segs.json and [scene_id].aggregation.json into the dataset/scannetv2/train and dataset/scannetv2/val folders according to the ScanNet v2 train/val split.

  • Copy the files [scene_id]_vh_clean_2.ply into the dataset/scannetv2/test folder according to the ScanNet v2 test split.

  • Put the file scannetv2-labels.combined.tsv in the dataset/scannetv2 folder.

The dataset files are organized as follows.

PointGroup
├── dataset
│   ├── scannetv2
│   │   ├── train
│   │   │   ├── [scene_id]_vh_clean_2.ply & [scene_id]_vh_clean_2.labels.ply & [scene_id]_vh_clean_2.0.010000.segs.json & [scene_id].aggregation.json
│   │   ├── val
│   │   │   ├── [scene_id]_vh_clean_2.ply & [scene_id]_vh_clean_2.labels.ply & [scene_id]_vh_clean_2.0.010000.segs.json & [scene_id].aggregation.json
│   │   ├── test
│   │   │   ├── [scene_id]_vh_clean_2.ply 
│   │   ├── scannetv2-labels.combined.tsv

(3) Generate input files [scene_id]_inst_nostuff.pth for instance segmentation.

cd dataset/scannetv2
python prepare_data_inst.py --data_split train
python prepare_data_inst.py --data_split val
python prepare_data_inst.py --data_split test

Training

CUDA_VISIBLE_DEVICES=0 python train.py --config config/pointgroup_run1_scannet.yaml 

You can start a tensorboard session by

tensorboard --logdir=./exp --port=6666

Inference and Evaluation

(1) If you want to evaluate on validation set, prepare the .txt instance ground-truth files as the following.

cd dataset/scannetv2
python prepare_data_inst_gttxt.py

Make sure that you have prepared the [scene_id]_inst_nostuff.pth files before.

(2) Test and evaluate.

a. To evaluate on validation set, set split and eval in the config file as val and True. Then run

CUDA_VISIBLE_DEVICES=0 python test.py --config config/pointgroup_run1_scannet.yaml

An alternative evaluation method is to set save_instance as True, and evaluate with the ScanNet official evaluation script.

b. To run on test set, set (split, eval, save_instance) as (test, False, True). Then run

CUDA_VISIBLE_DEVICES=0 python test.py --config config/pointgroup_run1_scannet.yaml

c. To test with a pretrained model, run

CUDA_VISIBLE_DEVICES=0 python test.py --config config/pointgroup_default_scannet.yaml --pretrain $PATH_TO_PRETRAIN_MODEL$

Pretrained Model

We provide a pretrained model trained on ScanNet v2 dataset. Download it here. Its performance on ScanNet v2 validation set is 35.2/57.1/71.4 in terms of mAP/mAP50/mAP25.

Visualize

To visualize the point cloud, you should first install mayavi. Then you could visualize by running

cd util 
python visualize.py --data_root $DATA_ROOT$ --result_root $RESULT_ROOT$ --room_name $ROOM_NAME$ --room_split $ROOM_SPLIT$ --task $TASK$

The visualization task could be input, instance_gt, instance_pred, semantic_pred and semantic_gt.

Results on ScanNet Benchmark

Quantitative results on ScanNet test set at the submisison time. scannet_result

TODO List

  • Distributed multi-GPU training

Citation

If you find this work useful in your research, please cite:

@article{jiang2020pointgroup,
  title={PointGroup: Dual-Set Point Grouping for 3D Instance Segmentation},
  author={Jiang, Li and Zhao, Hengshuang and Shi, Shaoshuai and Liu, Shu and Fu, Chi-Wing and Jia, Jiaya},
  journal={Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR)},
  year={2020}
}

Acknowledgement

This repo is built upon several repos, e.g., SparseConvNet, spconv and ScanNet.

Contact

If you have any questions or suggestions about this repo, please feel free to contact me ([email protected]).